Toward a Proton Plan Eric Prebys Fermilab Accelerator Division

1. Toward a Proton PlanEric PrebysFermilab Accelerator Division

2. Outline • Finley Report • Background • Linac • Booster • Main Injector • Proton Limitations • Projected Proton Demands • Experimental Requests • Proton Economics • Operational Issues and Current Performance • Recent Improvements • The Plan • The process • Near term • Issues for the next year • Longer term decisions PAC Meeting, December 12, 2003 - Prebys

3. Proton Team (“Finley Report”) • Group formed in early 2003 to study proton demands and needs for the “near” future (through ~2012 or so), in the absence of a proton driver. • Work culminated in a report to the director, available at www.fnal.gov/directorate/program_planning/studies/ProtonReport.pdf • This work will form the basis of “The Proton Plan”. • No big surprises [see P. Kasper “Getting Protons to NuMI (It’s a worry)”, 2001]. PAC Meeting, December 12, 2003 - Prebys

4. Preac(cellerator) and Linac “New linac”- 800 MHz “p cavities” accelerate H- ions from 116 MeV to 400 MeV “Preac” - Static Cockroft-Walton generator accelerates H- ions from 0 to 750 KeV. “Old linac”- 200 MHz “Alvarez tubes” accelerate H- ions from 750 keV to 116 MeV Preac/Linac can deliver about 45 mA of current for about 40 usec at a 15 Hz repetition rate (not a bottleneck) PAC Meeting, December 12, 2003 - Prebys

5. Booster • The 15 Hz cycle sets a fundamental clock rate for the entire complex. • One full booster “batch” sets a fundamental unit of protons throughout the accelerator complex (max 5E12). • 400 MeV Linac H- beam is injected into booster. • The lattice magnets in the Booster form a 15 Hz resonant circuit, setting the instantaneous cycle rate, but ramped elements limit the average repetition rate to somewhat lower. • From the Booster, beam can be directed to • The Main Injector • MiniBooNE • The Radiation Damage Facility (RDF) • A dump. PAC Meeting, December 12, 2003 - Prebys

6. Main Injector • The Main Injector can accept 8 GeV protons OR antiprotons from • Booster • The anti-proton accumulator • The Recycler (which shares the same tunnel) • It can accelerate protons to 120 GeV (in a minimum of 1.4 s) and deliver them to • The antiproton production target. • The fixed target area. • (soon) The NUMI beamline. • It can accelerate protons OR antiprotons to 150 GeV and inject them into the Tevatron. • The Main Injector holds six booster batches, in the absence of exotic loading schemes (slip stacking, RF barrier, etc). • It’s envisioned that two slipstacked batches will be used for stacking and the rest for NUMI and/or switchyard 120. PAC Meeting, December 12, 2003 - Prebys

7. What Limits Total Proton Intensity? • Maximum number of Protons the Booster can stably accelerate: 5E12 • Maximum average Booster rep. Rate: currently 7.5 Hz, may have to go to 10 Hz for NuMI+ (full) MiniBooNE • (NUMI only) Maximum number of booster batches the Main Injector can hold: currently 6 in principle, possibly go to 11 with fancy loading schemes in the future • (NUMI only) Minimum Main Injector ramp cycle time (NUMI only): 1.4s+loading time (at least 1/15s*nbatches) • Losses in the Booster: • Above ground radiation • Damage and/or activation of tunnel components Our biggest worry at the moment!!!! PAC Meeting, December 12, 2003 - Prebys

8. Fermilab Program • Major proton consumers (in order of demand): • MiniBooNE • NuMI (starting 2005) • Pbar production • Switchyard 120 Interest in Continuing MiniBooNE (or other 8 GeV line exp.) PAC Meeting, December 12, 2003 - Prebys

9. Preparing for the Neutrino Program • Shielding and new radiation assessment • Vastly improved loss monitoring. • Numerous hardware improvements • e.g new extraction septum and power supply • New tuning strategies. PAC Meeting, December 12, 2003 - Prebys

10. Proton Demand PAC Meeting, December 12, 2003 - Prebys

11. Demand: Summary • Pbar production • current: 0.9E16 p/hr • Max (slipstacking): 1.8E16 p/hr • MiniBooNE • current: ~3.5E16 p/hr • Request: 9E16 p/hr [5E20 p/yr] • NuMI • Baseline: 4.5E16 p/hr [2-2.5 p/yr] • Exotic loading schemes (~2006): ~7E16 p/hr [4E20 p/yr] • Occasionally claim: 14E16 p/hr [8E20 p/yr] • 2005 • Max pbar + MiniBooNE + baseline NuMI: ~16E16 p/hr (~4 times current limit!) What MINOS believes they are getting PAC Meeting, December 12, 2003 - Prebys

12. Understanding Proton Economics: Proton Timelines • Everything measured in 15 Hz “clicks” • Minimum Main Injector Ramp = 22 clicks = 1.4 s • MiniBoone batches “sneak in” while the MI is ramping. • Some Booster elements require 2 null prepulses before each 15 Hz batch train. • Cycle times of interest • Min. Stack cycle: 1 inj + 22 MI ramp = 23 clicks = 1.5 s • Min. NuMI cycle: 6 inj + 22 MI ramp = 28 clicks = 1.9 s • Full “Slipstack” cycle (one, scenario, total 11 batches): 6 inject+ 2 capture (6 -> 3)+ 2 inject+ 2 capture (2 -> 1)+ 2 inject+ 2 capture (2 -> 1)+ 1 inject+ 22 M.I. Ramp----------------------39 clicks = 2.6 s (More protons but longer cycle time) PAC Meeting, December 12, 2003 - Prebys

13. Proton Scenarios Booster Hardware Issues Booster Activation Issues PAC Meeting, December 12, 2003 - Prebys

14. The Bad News: Booster Tunnel Radiation Levels Any further increase in protons must come without increasing losses. PAC Meeting, December 12, 2003 - Prebys

15. Operational Issues: Limiting Booster Losses Maximum based on trip point 100 second running loss sums (normalized to trip point) Also limit total booster average power loss (B:BPL5MA) to 400W. Present rate PAC Meeting, December 12, 2003 - Prebys

16. How Have we been doing Power loss Total Protons Energy loss per proton (reduced by >3!) BooNE turn-on August 2003 PAC Meeting, December 12, 2003 - Prebys

17. Solving Problems: Extraction Doglegs • Each of the two Booster extraction septa has a set of vertical dogleg magnets to steer the beam around it during acceleration. • These magnets have an edge focusing effect which distorts the horizontal injection lattice: • 50% increase in maximum b • 100% increase in maximum dispersion. • Harmonic contributions. • This discovery was a direct result of increased Beam Physic involvement. • Effect goes like I2. Now tune to minimize. • Modified one of the two extraction regions during the recent shutdown to reduce problem (40% total reduction in lattice deviations) • Will do second next year • In then end, close to an 80% reduction in distortions Septum Dogleg Magnets PAC Meeting, December 12, 2003 - Prebys

18. Solving Problems: New Collimator System • Should dramatically reduce uncontrolled losses Basic Idea… A scraping foil deflects the orbit of halo particles… …and they are absorbed by thick collimators in the next periods. PAC Meeting, December 12, 2003 - Prebys

19. Other Major Shutdown Work • New Linac Lambertson • Should improve 400 MeV line optics • Simplifies linac tuning • Reduce losses • Four Large aperture Booster extraction magnets (EDWA) • Should reduce losses at extraction. • Complete vertical alignment network of Booster • First in ??? Years • Will be used to align entire machine • New power supply for second extraction region • Part of overall upgrade project • Linac water system upgrade • Booster vacuum system upgrade • Numerous other jobs PAC Meeting, December 12, 2003 - Prebys

20. How are we doing? • We’re getting there, but … Alignment problem found Protons/pulse to stacking Protons/pulse to MB p/hr total J/E12 Energy lost PAC Meeting, December 12, 2003 - Prebys

21. Formulating a Plan • The lab has recognized that the proton demands of the experimental program are significant, if not daunting, and will require substantial efforts to meet. • As the financial burden of Run II begins to ease, it’s envisioned that financial resources on the order of $20M will be diverted to these efforts over the next few years. • We are in the process of putting together a plan with the maximum likelihood of reaching these goals. • Ultimate goal is to generate a project similar to Run II • However, because the future (MiniBooNE) is already here, such a plan will necessarily have near and long term components. PAC Meeting, December 12, 2003 - Prebys

22. Near Term Priorities • Optimizing Booster for improved lattice: • Tuning and characterizing 400 MeV line (Linac to Booster). • Tuning Booster orbit to minimize losses. • Commission Collimators: • Once we have Booster optimized to the new lattice, we will begin to exercise the collimator system. • Estimate about 2 months to bring into standard operation. • Aperture Improvments: • Alignment • Complete (magnet) vertical network done over shutdown • Will analyze and effect moves when opportunities arise • Working on a systematic method for aligning straight sections. • Orbit control • Ramped orbit control program has been written. • Will be commissioned soon (new personnel) • Important now that collimator is in place. • Prototype RF Cavities • Two large aperture prototype cavities have been built, thanks to the help of MiniBooNE and NuMI universities. • We will install these as soon as they are ready to replace existing cavities which are highly activated. • It’s hoped this work will allow us to reach the MiniBooNE baseline this year. PAC Meeting, December 12, 2003 - Prebys

23. Issues over the Next Year • Linac Characterization and Reliability • Increase instrumentation of old linac to study instabilities. • Develop set of performance parameters. • Booster improvements. • Prepare for modification of second extraction region • New septum • Modified dogleg magnets • On track for next year’s shutdown. • Injection Bump (ORBUMP) Power Supply • Existing supply a reliability worry. • Limited to 7.5 Hz • Building new supply, capable of 15 Hz. • Aiming for next year’s shutdown. • Under consideration: New ORBUMP Magnets • Existing magnets limited by heating to 7.5 Hz • Working on a design for cooled versions. • These, with a new power supply, will make the Booster capable of sustained 15 Hz operation. • Biggest decision for the near future. PAC Meeting, December 12, 2003 - Prebys

24. Multibatch Timing • In order to Reduce radiation, a “notch” is made in the beam early in the booster cycle. • Currently, the extraction time is based on the counted number of revolutions (RF buckets) of the Booster. This ensures that the notch is in the right place. • The actual time can vary by > 5 usec! • This is not a problem if booster sets the timing, but it’s incompatible with multi-batch running (e.g. Slipstacking or NuMI) • We must be able to fix this total time so we can synchronize to the M.I. orbit. • This is called “beam cogging”. PAC Meeting, December 12, 2003 - Prebys

25. Active cogging • Detect slippage of notch relative to nominal and adjust radius of beam to compensate. Allow to slip by integer turns, maintaining the same total time. • Efforts in this area have been recently increased, with the help of a Minos graduate student (R. Zwaska). • Aim to get working in the next few months PAC Meeting, December 12, 2003 - Prebys

26. Long Term, Big $$ Ideas Under Consideration • New Booster RF system: • Larger aperture cavities (two prototypes will be installed soon). • New solid state preamps and modulators (would pay for itself in a few years). • New Linac front end: • Replace Preac and 200 MHz linac with RFQ feeding 400 MHz klystron-driven linac. • Addresses 7835 Amplifier Tube Problem • Possible part of proton driver? • Reduce Main Injector ramp time: • Still needs time to load protons • Needs to fit in with stacking. • Necessary to get the kind of protons that off-axis is talking about. PAC Meeting, December 12, 2003 - Prebys

27. Summary • We have a good understanding of the proton demands over the next few years in the context of the limitations of the Fermilab accelerator complex. • We have made remarkable progress toward meeting these demands, but are still falling well short. • We are pursuing an ambitious plan to attempt to meet these demands, but cannot yet guarantee its success. • The next few months will be very important. PAC Meeting, December 12, 2003 - Prebys

28. Extra Slides for Questions PAC Meeting, December 12, 2003 - Prebys

29. Multi-turn Ion Injection 4 pulsed “ORBUMP” magnets Circulating Beam DC “Septum” Beam at injection 400 MeV H-beam from LINAC Stripping foil • At injection, the 40 mA Linac H- beam is injected into the Booster over several “turns” (1 turn ~5E11). • The orbit is “bumped” out, so that both the injected beam and the circulating beam pass through a stripping foil, after which they circulate together. • At the moment, heating in the ORBUMP and power supply magnets limit our average rep rate (including prepulses to ~7.5 Hz). PAC Meeting, December 12, 2003 - Prebys

30. Booster RF System • 18 more or less original RF cavities and power supplies. • tunable from 38 to 53 MHz during acceleration. • 2 ¼” drift tube one of our primary aperture restrictions; new design being considered. • Existing cavities might overheat at >7.5Hz. Need to re-commission cooling • In-tunnel Power Amplifiers (PA’s) are by far the highest maintenance item in the Booster PAC Meeting, December 12, 2003 - Prebys

31. Booster Extraction (Two Extraction Regions) DC “doglegs” work with ramped 3-bump (BEXBUMP) to maintain 40p aperture below septum Fast (~40 ns) kickers PAC Meeting, December 12, 2003 - Prebys

32. Typical Booster Cycle Various Injected Intensities Transition Intensity (E12) Energy Lost (KJ) Time (s) PAC Meeting, December 12, 2003 - Prebys

33. Differential Loss Monitor Example: Collimators in – Collimators Out Collimator Position Relative Loss Time Position PAC Meeting, December 12, 2003 - Prebys

34. Dead Dog Studies • Took advantage of recent TeV Magnet failure to raise the Long 13 (dump) septum and turn off the associated dogleg. • Doglegs almost exactly add, so this should reduce the effect by almost half. • The mode of operation prevents short batching, booster study cycles and RDF operation. • Had about 36 hours of study in this mode. • Bottom Line: major improvement. PAC Meeting, December 12, 2003 - Prebys

35. Transmission After Tuning March 6, 7 turns, 1 dog March 3, 7 turns, both dogs PAC Meeting, December 12, 2003 - Prebys

36. Transmission with One Dogleg % Injected Charge (E12) PAC Meeting, December 12, 2003 - Prebys

37. Record Running w/o Dogleg PAC Meeting, December 12, 2003 - Prebys

38. The 7835 Power Triode – Our BIG Worry • Very complex technology • RF, material science, vacuum, chemistry • Similar to other tubes made by Burle • 4616 & 4617 • 7835 only used in the scientific community. • One military user for 4617 • Quality varies from decade to decade PAC Meeting, December 12, 2003 - Prebys

39. Tube Throughput with Burle • Median lifetime: 16 months • Recent lifetime: Less! (possibly related to vacuum problems) • We need about 3.41 tubes/year to maintain • Assuming historical median • With present tubes: twice that. • Burle now can make/rebuild ~20/year • Critical path: Final bakeout; two stands, 3-5 weeks bakeout • Also of concern: Supplier delivery time (e.g., ceramics, cathode) • Recently had four failures for one success!! • Delivery time: ~8 months, • But, often 12 months! • This is obviously a worry. PAC Meeting, December 12, 2003 - Prebys

40. Present 7835 Power Tube Situation • We’ve received 5 tubes since the last review • Only two delivered from Burle, after numerous failures • Two borrowed from BNL • One borrowed from Argonne • We now have one spare; we have frequently had zero; we have never had two. • Next one due “in August”. PAC Meeting, December 12, 2003 - Prebys